Inositol cyclic phosphates are produced by cleavage of phosphatidylphosphoinositols (polyphosphoinositides) with purified sheep seminal vesicle phospholipase C enzymes

Activated Inositol Phosphate, Substrate for Synthesis of Prostaglandylinositol Cyclic Phosphate (Cyclic PIP)-The Key for the Effectiveness of Inositol-Feeding

The natural cyclic AMP antagonist, prostaglandylinositol cyclic phosphate (cyclic PIP), is biosynthesized from prostaglandin E (PGE) and activated inositol phosphate (n-Ins-P), which is synthesized by a particulate rat-liver-enzyme from GTP and a precursor named inositol phosphate (pr-Ins-P), whose 5-ring phosphodiester structure is essential for n-Ins-P synthesis. Aortic myocytes, preincubated with [3H] myo-inositol, synthesize after angiotensin II stimulation (30 s) [3H] pr-Ins-P (65% yield), which is converted to [3H] n-Ins-P and [3H] cyclic PIP. Acid-treated (1 min) [3H] pr-Ins-P co-elutes with inositol (1,4)-bisphosphate in high performance ion chromatography, indicating that pr-Ins-P is inositol (1:2-cyclic,4)-bisphosphate. Incubation of [3H]-GTP with unlabeled pr-Ins-P gave [3H]-guanosine-labeled n-Ins-P. Cyclic PIP synthase binds the inositol (1:2-cyclic)-phosphate part of n-Ins-P to PGE and releases the [3H]-labeled guanosine as [3H]-GDP. Thus, n-Ins-P is most likely guanosine diphospho-4-inositol (1:2-cyclic)-phosphate. Inositol feeding helps patients with metabolic conditions related to insulin resistance, but explanations for this finding are missing. Cyclic PIP appears to be the key for explaining the curative effect of inositol supplementation: (1) inositol is a molecular constituent of cyclic PIP; (2) cyclic PIP triggers many of insulin's actions intracellularly; and (3) the synthesis of cyclic PIP is decreased in diabetes as shown in rodents.

A tale of two inositol trisphosphates

Between spring 1982 and autumn 1984 the physiological role of Ins(1,4,5)P3 as a calcium-mobilizing second messenger was first suggested and then experimentally established. At the same time the unexpected complexity of inositide metabolism began to be exposed by the discovery of Ins(1,3,4)P3. This article recalls my entanglement with these two inositol phosphates.

Identification of cellular target proteins for signaling cyclic phosphates

Cyclic glycerophosphates and their deoxy analogs were previously found to induce intracellular tyrosine and threonine phosphorylation in Chinese hamster ovary (CHO) cells. Further studies have indicated that these compounds induce neuronal outgrowth in PC-12 cells, as well as elevation of the state of cellular differentiation in human breast cancer cell lines. The mechanism by which these cyclic phosphates operate is not yet fully delineated. Using an affinity labeling approach we probed for possible cyclic phosphate target proteins in CHO cells. A 170 kDa protein that was labeled by an affinity cyclic phosphate reagent was identified by mass spectrometry as the largest subunit of the eukaryotic initiation factor 3 (eIF3). Using In-Gel kinase assays allowed the detection of a approximately 70 kDa target kinase directly activated by cyclic phosphates. Identification of these proteins may provide a basis for deciphering the mechanisms, by which cyclic phosphates exert their effects.

Degradation of the cyclic AMP antagonist prostaglandylinositol cyclic phosphate (cyclic PIP) by dephosphorylation

The cAMP antagonist, prostaglandylinositol cyclic phosphate (cyclic PIP), is synthesized from prostaglandin E and activated inositol phosphate. From various tissues only that amount of cyclic PIP can be isolated that constitutes the difference between synthesis and degradation. In order to overcome this drawback, the cyclic PIP degrading enzyme or enzymes had to be characterized prior to searching for inhibitors. Cyclic PIP degrading activities have been found in all rat tissues tested, and are lowest in brain (380 pmol x min(-1) x g(-1) wet weight) and highest in liver (1460 pmol x min(-1) x g(-1) wet weight). They are associated primarily with particulate structures of the cells, but not with the plasma membrane. There appear to be at least two different enzymatic activities involved in the degradation of cyclic PIP, because there are two pH-optima, one between pH 7 and 8 and another between pH 4 and 5. It is assumed that these activities are located in microsomes and lysosomes. Because prostaglandylinositol is the final product obtained in the degradation of cyclic PIP, a phosphodiesterase and a phosphatase should be involved, which could not yet be identified individually. Like alkaline phosphatase, cyclic PIP-degrading enzymes require Mg2+ and they are inhibited by heavy metal ions such as mercuric and copper chloride, by sodium fluoride and interestingly, by prostaglandins.

Demonstration of the presence of cyclic inositol phosphohydrolase in human urine

Cyclic inositol phosphohydrolase (cIPH), cleaves the cyclic bond of cyclic inositol monophosphate (cIP) to yield inositol monophosphate. In this communication, we demonstrate the presence of cIPH in human urine. cIPH was measured in the 24-h urine samples of both male and female hospital patients. cIPH released per day ranged from 0 to 243 units in men (n = 16) and from 15 to 346 units in women (n = 18). Release of cIPH activity was not related to renal function as measured by creatinine clearance. HPLC ion-exchange chromatography or HPLC gel filtration of ammonium sulfate precipitate yielded a distinct cIPH peak with an apparent molecular weight of 40 kDa on gel filtration. This is the first demonstration of the presence of this enzyme in human urine. The large variation (over 20-fold) in the excretion of this protein suggests that it may have physiological and/or pathological significance.

Dissociation of cyclic inositol phosphohydrolase activity from annexin III

Cyclic inositol phosphohydrolase is a phosphodiesterase that cleaves the cyclic bond of cyclic inositol monophosphate. In 1990, Ross et al. (Ross, T. S., Tait, J. F., and Majerus, P. W. (1990) Science 248, 605-607) purified this enzyme from human placenta and reported that cyclic inositol phosphohydrolase is identical to annexin III. Independent confirmation of this finding has not been provided. The relative distribution of annexin III and cyclic inositol phosphohydrolase activity in rat kidney and spleen indicated that annexin III can be dissociated from cyclic inositol phosphohydrolase activity. Rat spleen contains large quantities of annexin III, but has very little cyclic inositol phosphohydrolase activity. In contrast, rat kidney, one of the richest sources of cyclic inositol phosphohydrolase activity, possesses very little (immunohistochemistry) or no (Western blot) annexin III. Similar to cytosol of human placenta, cytosol of guinea pig kidney contains both annexin III and cyclic inositol phosphohydrolase. On SDS-gel electrophoresis, guinea pig kidney annexin III has a slightly different mobility than the human placental annexin III. Human placental annexin III co-migrates with cyclic inositol phosphohydrolase on ion exchange chromatography, while guinea pig kidney annexin III is clearly dissociated from cyclic inositol phosphohydrolase on ion exchange chromatography. Both guinea pig kidney annexin III and human placental annexin III pellet with the addition of calcium and centrifugation, while cyclic inositol phosphohydrolase activity in both of these tissues remains in the supernatant. Our studies clearly show that cyclic inositol phosphohydrolase and annexin III are two different proteins.

Time-dependent effects of lithium on the agonist-stimulated accumulation of second messenger inositol 1,4,5-trisphosphate in SH-SY5Y human neuroblastoma cells

In order to approach the molecular mechanism of Li+'s mood-stabilizing action, the effect of Li+ (LiCl) on inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] mass was investigated in human neuroblastoma SH-SY5Y cells, which express muscarinic M3 receptors, coupled to PtdIns hydrolysis. Stimulation of these cells, with the cholinergic agonist acetylcholine, resulted in a rapid and transient increase in Ins(1,4,5)P3 with a maximum at 10 s. This was followed by a rapid decline in Ins(1,4,5)P3 within 30 s to a plateau level above baseline, which gradually declined to reach a new steady state, which was significantly higher than resting Ins(1,4,5)P3 at 30 min. Li+ had no effect on Ins(1,4,5)P3 in resting cells, as well as on the acetylcholine-dependent peak of Ins(1,4,5)P3. However, Li+ caused a transient reduction (at 45 s), followed by a long lasting increase in the Ins(1,4,5)P3 (30 min), as compared with controls. The Li+ effects were dose-dependent and were observed at concentrations used in the treatment of bipolar disorders. Supplementation with inositol had no effect on the level of Ins(1,4,5)P3, at least over the time periods studied. Stimulation of muscarinic receptors with consequent activation of phospholipase C were necessary for the manifestation of Li+ effects in SH-SY5Y cells, Li+ did not interfere with degradation of Ins(1,4,5)P3 after receptor-blockade with atropine, suggesting that Li+ has no direct effect on the Ins(1,4,5)P3-metabolizing enzymes. A direct effect of Li+ on the phospholipase C also is unlikely. Blockade of Ca2+ entry into the cells by Ni2+, or incubation with EGTA, which reduces agonist-stimulated accumulation of Ins(1,4,5)P3, had no effect on the Li(+)-dependent increase in Ins(1,4,5)P3.

The inhibition of phosphoinositide synthesis and muscarinic-receptor-mediated phospholipase C activity by Li+ as secondary, selective, consequences of inositol depletion in 1321N1 cells

Conditions are described for culture of 1321N1 cells under which cellular inositol is decreased from approximately 20 mM to < 0.5 mM but phosphoinositide concentrations are unaffected. The effects of the muscarinic-receptor agonist carbachol (1 mM) and/or LiCl (10 mM) on phosphoinositide turnover in these or in inositol-replete cells was examined after steady-state [3H]inositol labelling of phospholipid pools. In both inositol-replete and -depleted cells, carbachol stimulated similar initial (0-15 min) rates of phospholipase C (PLC) activity, in the presence of Li+. Subsequently (> 30-60 min) stimulated PLC activity and [3H]PtdIns concentrations declined dramatically only in depleted cells. In inositol-depleted cells, carbachol alone evoked increased concentrations of [3H]inositol, [3H]InsP1, [3H]InsP2, [3H]InsP3 and [3H]InsP4, which were largely sustained over 90 min, and concentrations of [3H]PtdIns, [3H]PtdInsP and [3H]PtdInsP2 were decreased only to approximately 82, 84 and 93% of control respectively. In the presence of Li+ in these cells, the stimulated rise in [3H]inositol was prevented and, although accumulation of [3H]InsP1, [3H]InsP2 and [3H]InsP3 was initially (0-30 min) potentiated, rates of accumulation of [3H]InsP1 and concentrations of [3H]polyphosphates later (> 30-60 min) declined, and concentrations of [3H]PtdIns, [3H]PtdInsP and [3H]PtdInsP2 were decreased respectively to approximately 39, 48 and 81% of control. After 60 min in the presence of both carbachol and Li+, stimulated PLC activity was decreased by approximately 70% compared with the initial rate in depleted cells. This decreased PLC activity was reflected by changes in the stimulated concentrations of [3H]Ins(1,3,4)P3 but not of [3H]Ins(1,4,5)P3, but effects of Li+ on the latter may have been obscured by the demonstrated, concomitant and equal stimulated accumulation of [3H]inositol 1:2cyclic,4,5-trisphosphate. These data suggest that receptor-mediated PLC activity is selectively impaired by Li+ as a secondary consequence of inositol monophosphatase inhibition in cells which are highly dependent on inositol re-cycling, but imply that, although Li+ attenuation of PLC activity correlates closely with parameters indicative of limiting inositol supply, it is not readily attributed to decreased PtdInsP2 availability. The potential for complex regulation of PLC and PtdIns synthase is discussed.

The endogenous cyclic AMP antagonist, cyclic PIP: its ubiquity, hormone-stimulated synthesis and identification as prostaglandylinositol cyclic phosphate

This report shows that the cyclic AMP antagonist cyclic PIP is present in all organs and tissues of the rat so far examined: brain, heart, lung, intestine, kidney, liver, spleen, skeletal muscle and fat. The synthesis of cyclic PIP is stimulated by insulin or noradrenaline (alpha-adrenergic action) in a dose-dependent fashion. Increasing cyclic PIP synthesis with increasing insulin concentrations matches the insulin receptor binding curves. Cyclic PIP levels in blood serum remain low after hormonal stimulation and no cyclic PIP can be detected in urine. As an indication of its ubiquity, cyclic PIP was even detected in yeast. Prostaglandin E (as shown by incorporation of [3H]PGE into cyclic PIP and demonstration of a constant specific activity), myo-inositol (as shown by acid hydrolysis of the dephosphorylated cyclic PIP and mass spectrometric identification of the products) and one phosphate (as shown by the ionic nature of cyclic PIP and its inactivation by phosphodiesterase plus phosphatase) are components of cyclic PIP. Chemical derivatization experiments of cyclic PIP suggest the phosphate to be bound to myo-inositol and the myo-inositol phosphate to the prostaglandin E by its C15-hydroxyl group.

Phospholipids chiral at phosphorus. Stereochemical mechanism for the formation of inositol 1-phosphate catalyzed by phosphatidylinositol-specific phospholipase C

The phosphatidylinositol-specific phospholipase C (PI-PLC) from mammalian sources catalyzes the simultaneous formation of both inositol 1,2-cyclic phosphate (IcP) and inositol 1-phosphate (IP). It has not been established whether the two products are formed in sequential or parallel reactions, even though the latter has been favored in previous reports. This problem was investigated by using a stereochemical approach. Diastereomers of 1,2-dipalmitoyl-sn-glycero-3-(1D- [16O,17O]phosphoinositol) ([16O,17O]DPPI) and 1,2-dipalmitoyl-sn-glycero-3-(1D-thiophosphoinositol) (DPPsI) were synthesized, the latter with known configuration. Desulfurization of the DPPsI isomers of known configurations in H2(18)O gave [16O,18O]DPPI with known configurations, which allowed assignment of the configurations of [16O,17O]DPPI on the basis of 31P NMR analyses of silylated [16O,18O]DPPI and [16O,17O]DPPI (the inositol moiety was fully protected in this operation). (Rp)- and (Sp)-[16O,17O]DPPI were then converted into trans- and cis-[16O,17O]IcP, respectively, by PI-PLC from Bacillus cereus, which had been shown to proceed with inversion of configuration at phosphorus [Lin, G., Bennett, F. C., & Tsai, M.-D. (1990) Biochemistry 29, 2747-2757]. 31P NMR analysis was again used to differentiate the silylated products of the two isomers of IcP, which then permitted assignments of IcP with unknown configuration derived from transesterification of (Rp)- and (Sp)-[16O,17O]DPPI by bovine brain PI-PLC-beta 1. The results indicated inversion of configuration, in agreement with the steric course of the same reaction catalyzed by PI-PLCs from B. cereus and guinea pig uterus reported previously. For the steric course of the formation of inositol 1-phosphate catalyzed by PI-PLC, (Rp)- and (Sp)-[16O,17O]DPPI were hydrolyzed in H2(18)O to afford 1-[16O,17O,18O]IP, which was then converted to IcP chemically and analyzed by 31P NMR. The results indicated that both B. cereus PI-PLC and the PI-PLC-beta 1 from bovine brain catalyze conversion of DPPI to IP with overall retention of configuration at phosphorus. These results suggest that both bacterial and mammalian PI-PLCs catalyze the formation of IcP and IP by a sequential mechanism. However, the conversion of IcP to IP was detectable by 31P NMR only for the bacterial enzyme. Thus an alternative mechanism in which IcP and IP are formed by totally independent pathways, with formation of IP involving a covalent enzyme-phosphoinositol intermediate, cannot be ruled out for the mammalian enzyme. It was also found that both PI-PLCs displayed lack of stereo-specifically toward the 1,2-diacylglycerol moiety, which suggests that the hydrophobic part of phosphatidylinositol is not recognized by PI-PLC.

Identity of inositol 1,2-cyclic phosphate 2-phosphohydrolase with lipocortin III

The amino acid sequences of three fragments of cyanogen bromide-digested human placental inositol 1,2-cyclic phosphate 2-phosphohydrolase, an enzyme of the phosphatidylinositol signaling pathway, are identical to sequences within lipocortin III, a member of a family of homologous calcium- and phospholipid-binding proteins that do not have defined physiological functions. Lipocortin III has also been previously identified as placental anticoagulant protein III (PAP III) and calcimedin 35 alpha. Antibodies to PAP III detected PAP III and inositol 1,2-cyclic phosphate 2-phosphohydrolase with identical reactivity on immunoblotting. In addition, inositol 1,2-cyclic phosphate 2-phosphohydrolase was stimulated by the same acidic phospholipids that bind lipocortins.

Phospholipids chiral at phosphorus. Stereochemical mechanism of reactions catalyzed by phosphatidylinositide-specific phospholipase C from Bacillus cereus and guinea pig uterus

(Rp)- and (Sp)-1,2-dipalmitoyl-sn-glycero-3-thiophosphoinositol (DPPsI) were synthesized as a mixture and their configurations assigned on the basis of the stereospecific hydrolysis catalyzed by phospholipase A2 (PLA2) from bee venom. PLA2 is known to be stereospecific to the Rp isomer of 1,2-dipalmitoyl-sn-glycero-3-thiophosphocholine (DPPsC) and 1,2-dipalmitoyl-sn-glycero-3-thiophosphoethanolamine (DPPsE). Since the configurations of (Rp)- and (Sp)-DPPsI correspond to those of (Sp)- and (Rp)-DPPsC, respectively, due to a change in priority, the isomer specifically hydrolyzed by PLA2 was assigned to (Sp)-DPPsI. The DPPsI analogues were then used to probe the mechanism and to elucidate the steric course of the reaction catalyzed by phosphatidylinositide-specific phospholipase C (PI-PLC) from Bacillus cereus and for both isozyme I and isozyme II of PI-PLC from guinea pig uterus. It was found that the Rp isomer of DPPsI is the preferred substrate for all three PI-PLCs. Thus PI-PLC shows the same stereospecificity as phosphatidylcholine-specific PLC (PC-PLC), which prefers the Sp isomer of DPPsC. The ratio of the two products inositol 1,2-cyclic phosphorothioate (cIPs) and inositol phosphorothioate (IPs) was not significantly perturbed by the use of phosphorothioate analogue for all three PI-PLCs, which implies that IPs is not produced by enzyme-mediated ring opening of cIPs and supports a parallel pathway for the formation of both products. In order to elucidate the steric course of the cyclization reaction, exo and endo isomers of cIPs were synthesized and their absolute configurations at phosphorus were determined by nuclear magnetic resonance and other techniques. It was found that exo-cIPs is the product produced by all three PI-PLCs. Thus the steric course of the conversion DPPsI to cIPs catalyzed by all three PI-PLCs was inversion of configuration at phosphorus. These results taken together suggest that the reaction catalyzed by PI-PLC most likely proceeds via direct attack by the 2-OH group to generate the cyclic product, and parallelly by water to generate the noncyclic inositol phosphates, without involving a covalent enzyme-phosphoinositol intermediate.

Inositol phosphate metabolism and signal transduction

Activation of a variety of cell surface receptors results in a biphasic increase in the cytoplasmic Ca2+ concentration, due to the release or mobilization of intracellular Ca2+ stores and to the entry of Ca2+ from the extracellular space. Stimulation of these same receptors also results in the hydrolysis of the minor plasma membrane phospholipid, phosphatidylinositol 4,5-bisphosphate, with the concomitant formation of (1,4,5)inositol trisphosphate [(1,4,5)IP3] and diacylglycerol. It is well established that phosphatidylinositol 4,5-bisphosphate hydrolysis is responsible for the changes in Ca2+ homeostasis. There is strong evidence that (1,4,5)IP3 stimulates Ca2+ release from intracellular stores. The Ca2(+)-releasing actions of (1,4,5)IP3 are terminated by its metabolism through two distinct pathways: (1,4,5)IP3 is dephosphorylated by a 5-phosphatase to (1,4)IP2; alternatively, (1,4,5)IP3 is phosphorylated to (1,3,4,5)IP4 by a 3-kinase. Whereas the mechanism of Ca2+ mobilization is understood, the precise mechanisms involved in Ca2+ entry are not known. A recent proposal that (1,4,5)IP3, by emptying an intracellular Ca2+ pool, secondarily elicits Ca2+ entry will be considered. This review summarizes recent studies of the mechanisms by which inositol phosphates regulate cytoplasmic Ca2+ concentrations.

Inositol phosphate formation and its relationship to calcium signaling

The activation of a variety of cell surface receptors results in a biphasic increase in the cytoplasmic Ca2+ concentration due to the release or mobilization of Ca2+ from intracellular stores and to the entry of Ca2+ from the extracellular space. It is well established that phosphatidylinositol 4,5-bisphosphate hydrolysis is responsible for the changes in Ca2+ homeostasis. Stimulation of Ca2(+)-mobilizing receptors also results in the phospholipase C-catalyzed hydrolysis of the minor plasma membrane phospholipid, phosphatidylinositol 4,5-bisphosphate, with the concomitant formation of inositol (1,4,5) trisphosphate [1,4,5)IP3) and diacylglycerol. Analogous to the adenylyl cyclase signaling system, receptor-mediated stimulation of phospholipase C also appears to be mediated by one or more intermediary guanine nucleotide-dependent regulatory proteins. There is strong evidence that (1,4,5)IP3 stimulates Ca2+ release from intracellular stores. The Ca2(+)-releasing actions of (1,4,5)IP3 are terminated by its metabolism through two distinct pathways. (1,4,5)IP3 is dephosphorylated by a 5-phosphatase to inositol (1,4) bisphosphate; alternatively, (1,4,5)IP3 can be phosphorylated to inositol (1,3,4,5) tetrakisphosphate by a 3-kinase. Whereas the mechanism of Ca2+ mobilization is understood, the precise mechanisms involved in Ca2+ entry are not known. A recent proposal that (1,4,5)IP3 secondarily elicits Ca2+ entry by emptying an intracellular Ca2+ pool will be considered. This review summarizes our current understanding of the mechanisms by which inositol phosphates regulate cytoplasmic Ca2+ concentrations.

Aging of rat heart myocytes disrupts muscarinic receptor coupling that leads to inhibition of cAMP accumulation and alters the pathway of muscarinic-stimulated phosphoinositide hydrolysis

The biochemical responses to muscarinic stimulation (inhibition of isoproterenol-stimulated cAMP accumulation and stimulation of phosphoinositide turnover) were investigated in intact myocyte cultures prepared from the hearts of newborn rats. The studies employed young (5 days after plating) and aged (14 days old) myocyte cultures. Aging of the myocyte cultures was accompanied by marked alterations in both the inhibition of cAMP accumulation and the stimulation of the phosphoinositide metabolism via the muscarinic receptors. However, the effects on the two muscarinic responses were different. The first response was disrupted at the level of the coupling of the muscarinic receptors with adenylate cyclase through Gi. On the other hand, muscarinic stimulation of phosphoinositide hydrolysis still occurred in the aged myocyte cultures; however, the inositol trisphosphate generated was not converted to inositol 1-phosphate as in young cultures or as in aged cultures stimulated by norepinephrine. This raises the possibility that muscarinic activation of aged myocyte cultures shifts the metabolic state of the cells and alters the pathway of phosphoinositide hydrolysis. Treatment of aging cultures with phosphatidylcholine liposomes under conditions that yielded aged myocyte cultures with a lipid composition resembling that of young ones restored the muscarinic effect on cAMP accumulation, where the impairment in aged cultures was at the coupling stage (which takes place in the plasma membrane). This treatment had no effect on the response of the phosphoinositide metabolism to muscarinic stimulation.

Peptide hormones, cytosolic calcium and renal epithelial response

We have reviewed the evidence that a number of hormones interact with renal tubular epithelial cells. The evidence suggests that in the mammalian renal tubule bradykinin and parathyroid hormone interact with cell surface receptors to initiate the hydrolysis of PIP2 leading to the formation of I 1,4,5P3 and diacylglycerol in the distal and proximal tubule, respectively. The activation of this second messenger system leads to the mobilization of Ca2+ from intracellular stores. Vasopressin does not activate this second messenger system in mammalian renal epithelial cells, and we cannot demonstrate I 1,4,5P3 formation and Ca2+ mobilization either in the rabbit papillary collecting tubules or in MDCK cells. There is evidence emerging, but not discussed here, that angiotensin II may also mediate some of its effects on the mammalian proximal tubule via the inositol polyphosphate second messenger system.

Characterization of the cross-reacting determinant (CRD) of the glycosyl-phosphatidylinositol membrane anchor of Trypanosoma brucei variant surface glycoprotein

The cross-reacting determinant (CRD epitope) of the glycosyl-phosphatidylinositol (GPI) membrane anchor of Trypanosoma brucei variant surface glycoprotein has been analysed by selective chemical and enzymic modification of the isolated GPI structure combined with the use of a competitive ELISA inhibition assay for the detection of CRD epitopes. The data show that the CRD consists of at least three overlapping epitopes involving different regions of the molecule including the inositol 1,2-cyclic phosphate, the non-N-acetylated-glucosamine residue and the galactose branch. Although the presence of all three of these structural features is required for quantitative binding of anti-CRD antibodies in ELISA and Western blotting, the Western blot reaction obtained in the presence of any one epitope is still significant. The use of anti-CRD antibodies for the detection of GPI anchors is discussed.

Inositol phosphates: proliferation, metabolism and function

After the initial discovery of receptor-linked generation of inositol(1,4,5)trisphosphate (Ins(1,4,5)P3) it was generally assumed that Ins(1,4,5)P3 and its proposed breakdown products inositol(1,4)bisphosphate (Ins(1,4)P2) and Ins1P, along with cyclic inositol monophosphate, were the only inositol phosphates found in significant amounts in animal cells. Since then, three levels of complexity have been introduced. Firstly, Ins(1,4,5)P3 can be phosphorylated to Ins(1,3,4,5)P4, and the subsequent metabolism of these two compounds has been found to be intricate and probably different between various tissues. The functions of Ins(1,4,5)P3 and Ins(1,3,4,5)P4 are almost certainly to regulate cytosolic Ca2+ concentrations, but the reasons for the labyrinth of the metabolic pathways after their deactivation by a specific 5-phosphatase remain obscure. Secondly, inositol pentakis- and hexakisphosphates have been found in many animal cells other than avian erythrocytes. It has been shown that their synthesis pathway is entirely separate from the inositol phosphates discussed above, both in terms of many of the isomers involved and probably in the subcellular localization; some possible functions of InsP5 and InsP6 are discussed here. Thirdly, cyclic inositol polyphosphates have been reported in stimulated tissues; the evidence for their occurrence in vivo and their possible physiological significance are also discussed.

Phosphoinositide hydrolysis by guanosine 5'-[gamma-thio]triphosphate-activated phospholipase C of turkey erythrocyte membranes

Phosphatidylinositol (PtdIns), phosphatidylinositol 4-phosphate (PtdIns4P) and phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] of turkey erythrocytes were labelled by using either [32P]Pi or [3H]inositol. Although there was little basal release of inositol phosphates from membranes purified from labelled cells, in the presence of guanosine 5'-[gamma-thio]triphosphate (GTP[S]) the rate of accumulation of inositol bis-, tris- and tetrakis-phosphate (InsP2, InsP3 and InsP4) was increased 20-50-fold. The enhanced rate of accumulation of 3H-labelled inositol phosphates was linear for up to 20 min; owing to decreases in 32P specific radioactivity of phosphoinositides during incubation of membranes with unlabelled ATP, the accumulation of 32P-labelled inositol phosphates was linear for only 5 min. In the absence of ATP and a nucleotide-regenerating system, no InsP4 was formed, and the overall inositol phosphate response to GTP[S] was decreased. Analyses of phosphoinositides during incubation with ATP indicated that interconversions of PtdIns to PtdIns4P and PtdIns4P to PtdIns(4,5)P2 occurred to maintain PtdIns(4,5)P2 concentrations; GTP[S]-induced inositol phosphate formation was accompanied by a corresponding decrease in 32P- and 3H-labelled PtdIns, PtdIns4P and PtdIns(4,5)P2. In the absence of ATP, only GTP[S]-induced decreases in PtdIns(4,5)P2 occurred. Since inositol monophosphate was not formed under any condition, PtdIns is not a substrate for the phospholipase C. The production of InsP2 was decreased markedly, but not blocked, under conditions where Ins(1,4,5)P3 5-phosphomonoesterase activity in the preparation was inhibited. Thus the predominant substrate of the GTP[S]-activated phospholipase C of turkey erythrocyte membranes is PtdIns(4,5)P2. Ins(1,4,5)P3 was the major product of this reaction; only a small amount of Ins(1:2-cyclic, 4,5)P3 was released. The effects of ATP on inositol phosphate formation apparently involve the contributions of two phenomena. First, the P2-receptor agonist 2-methylthioadenosine triphosphate (2MeSATP) greatly increased inositol phosphate formation and decreased [3H]PtdIns4P and [3H]PtdIns(4,5)P2 in the presence of a low (0.1 microM) concentration of GTP[S]. ATP over the concentration range 0-100 microM produced effects in the presence of 0.1 microM-GTP[S] essentially identical with those observed with 2MeSATP, suggesting that the effects of low concentrations of ATP are also explained by a stimulation of P2-receptors. Higher concentrations of ATP also increase inositol phosphate formation, apparently by supporting the synthesis of substrate phospholipids.(ABSTRACT TRUNCATED AT 400 WORDS)

Inositol 1:2(cyclic),4,5-trisphosphate is not a major product of inositol phospholipid metabolism in vasopressin-stimulated WRK1 cells

1. A method has been devised for quenching cell incubations with an aqueous phenol/chloroform/EDTA mixture of neutral pH, to allow the analysis of acid-labile cell components. 2. Using this method, we have searched for the appearance of Ins(1:2cyclic,4,5)P3 [inositol 1:2(cyclic),4,5-trisphosphate] in WRK1 mammary tumour cells that were labelled to high specific radioactivity with [3H]inositol and then stimulated with 0.4 microM-vasopressin. 3. Vasopressin caused a very rapid accumulation of Ins(1,4,5)P3 (inositol 1,4,5-trisphosphate), followed by a slower decline towards the original concentration. An acid-labile and inositol-labelled compound with the chromatographic properties of Ins(1:2cyclic,4,5)P3 was present in unstimulated cells at less than 5% of the elevated concentration of Ins(1,4,5)P3. Its concentration rose 2-3-fold during stimulation for 3 min, at which time its concentration was about 5% of the elevated concentration of Ins(1,4,5)P3. 4. We conclude that Ins(1,4,5)P3 is the major product of phosphoinositidase C-catalysed phosphatidylinositol 4,5-bisphosphate hydrolysis in vasopressin-stimulated WRK1 cells. Ins(1:2cyclic,4,5)P3 is unlikely to be an important intracellular messenger in these cells, at least during the first few minutes of stimulation.

Does phospholipase C inhibit fusion between hamster sperm and zona-free eggs?

Previous studies (Hirao and Yanagimachi: Gamete Res. 1:3-12, 1978) have found that phospholipase C (PLC) preparations inhibit sperm-egg fusion. We have attempted to duplicate these results with PLC, as well as with a more specific enzyme, phosphatidylinositol-specific PLC. PLC preparations were applied externally to zona-free hamster eggs prior to incubation with sperm. Phosphatidylinositol-specific PLC did not inhibit sperm penetration. The degree of sperm-egg fusion observed after egg exposure to PLC, however, was dependent upon the purity of the commercial preparation. An impure sample of PLC inhibited sperm penetration, while a more purified preparation did not. The morphology of eggs was unaffected by exposure to phosphatidylinositol-specific PLC and the more purified PLC preparation. The impure preparation, however, was disruptive primarily to the egg plasma membrane as well as to internal organelle organization. The degree of damage by the impure PLC preparation was concentration dependent. The results suggest that as purity of the PLC preparation is increased, the adverse effects of PLC on sperm-egg fusion become negligible.

Isolation of 1-monomethylphosphoinositol 4,5-bisphosphate [a product of methanolysis of inositol 1,2-(cyclic)-4,5-trisphosphate] from Swiss mouse 3T3 cells

We have noted two previously undescribed inositol polyphosphates in neutral methanol extracts from Swiss mouse 3T3 cells that were grown in [3H]inositol and stimulated with platelet-derived growth factor. They have been identified as 1-monomethylphosphoinositol 4,5-bisphosphate and 1-monomethylphosphoinositol 4-phosphate by comparison to a synthesized standard using HPLC chromatography, paper electrophoresis, and enzymatic dephosphorylation with inositol polyphosphate 5-phosphomonoesterase and intestinal alkaline phosphatase [orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1]. We propose that these compounds are formed by methanolysis of inositol 1,2-(cyclic)-4,5-trisphosphate and inositol 1,2-(cyclic)-4-bisphosphate present in the cells. Inositol cyclic phosphates did not react with neutral methanol in the absence of the cells, which are required for the methanolysis reaction. These findings suggest a role for inositol cyclic phosphates as reactive compounds that are added to as yet unidentified cellular acceptors.

Inositol phospholipid hydrolysis by rat sciatic nerve phospholipase C

Rat sciatic nerve cytosol contains a phosphodiesterase of the phospholipase C type that catalyzes the hydrolysis of inositol phospholipids, with preferences of phosphatidylinositol 4'-phosphate (PIP) greater than phosphatidylinositol (PI) much greater than phosphatidylinositol 4',5'-bisphosphate (PIP2), at a pH optimum of 5.5-6.0 and at maximum rates of 55, 13, and 0.7 nmol/min/mg protein, respectively. Analysis of reaction products by TLC and formate exchange chromatography shows that inositol 1,2-cyclic phosphate (83%) and diacylglycerol are the major products of PI hydrolysis. [32P]-PIP hydrolysis yields inositol bisphosphate, inositol phosphate, and inorganic phosphate, indicating the presence of phosphodiesterase, phosphomonoesterase, and/or inositol phosphate phosphatase activities in nerve cytosol. Phosphodiesterase activity is Ca2+-dependent and completely inhibited by EGTA, but phosphomonoesterase activity is independent of divalent cations or chelating agents. Phosphatidylcholine (PC) and lysophosphatidylcholine (lysoPC) inhibit PI hydrolysis. They stimulate PIP and PIP2 hydrolysis up to equimolar concentrations, but are inhibitory at higher concentrations. Both diacylglycerols and free fatty acids stimulate PI hydrolysis and counteract its inhibition by PC and lysoPC. PIP2 is a poor substrate for the cytosolic phospholipase C and strongly inhibits hydrolysis of PI. However, it enhances PIP hydrolysis up to an equimolar concentration.

Characterization of the inositol 1,4,5-trisphosphate-induced Ca2+ release in pancreatic beta-cells

Pancreatic beta-cells isolated from obese-hyperglycaemic mice released intracellular Ca2+ in response to carbamoylcholine, an effect dependent on the presence of glucose. The effective Ca2+ concentration reached was sufficient to evoke a transient release of insulin. When the cells were deficient in Ca2+, the Ca2+ pool sensitive to carbamoylcholine stimulation was equivalent to that released by ionomycin. Unlike intact cells, cells permeabilized by high-voltage discharges failed to generate either inositol 1,4,5-triphosphate (InsP3) or to release Ca2+ after exposure to carbamoylcholine. However, the permeabilized cells released insulin sigmoidally in response to increasing concentrations of Ca2+. Also in the absence of functional mitochondria these cells exhibited a large ATP-dependent buffering of Ca2+, enabling the maintenance of an ambient Ca2+ concentration corresponding to about 150 nM even after several additional pulses of Ca2+. InsP3, maximally effective at 6 microM, promoted a rapid and pronounced release of Ca2+. The InsP3-sensitive Ca2+ pool was rapidly filled and lost its Ca2+ late after ATP depletion. The transient nature of the Ca2+ signal was not overcome by repetitive additions of InsP3. It was possible to restore the response to InsP3 after a delay of approx. 20 min, an effect which had less latency after the addition of Ca2+. These latter findings argue against degradation and/or desensitization as factors responsible for the transiency in InsP3 response. It is suggested that Ca2+ released by InsP3 is taken up by a part of the endoplasmic reticulum (ER) not sensitive to InsP3. On metabolism of InsP3, Ca2+ recycles to the InsP3-sensitive pool, implying that this pool indeed has a very high affinity for the ion. The presence of functional mitochondria did not interfere with the recycling process. The ER in pancreatic beta-cells is of major importance in buffering Ca2+, but InsP3 only modulates Ca2+ transport for a restricted period of time following immediately upon its formation. Thereafter the non-sensitive part of the ER takes over the continuous regulation of Ca2+ cycling.

H.p.l.c. analysis of inositol monophosphate isomers formed on angiotensin II stimulation of rat adrenal glomerulosa cells

[3H]Inositol-prelabelled isolated rat adrenal glomerulosa cells were stimulated with 25 nM-AII ([Asp1, Ile5]-angiotensin II) in the presence of 10 mM-Li+, and the resulting inositol monophosphate isomers were separated successfully by using a recently developed h.p.l.c. methodology. Two major peaks of radioactivity were detected which showed the same retention characteristics on h.p.l.c. as inositol 4-phosphate and inositol 1-phosphate and which increased 5-fold and 8-fold respectively on stimulation with AII. In addition, a relatively small peak with the retention characteristics of inositol 1:2-cyclic phosphate was seen to undergo a 1.5-fold increase on stimulation. This was not considered sufficient to suggest that cyclic phosphoinositols were a major product of AII-stimulated phosphoinositide turnover. No peaks of radioactive material were detected in the regions expected for inositol 2-phosphate (an acid hydrolysis product of inositol 1:2-cyclic phosphate) or inositol 5-phosphate. These results establish the identity of the major inositol phosphate products in AII-stimulated glomerulosa cells and confirm and extend the previous observations of Balla, Baukal, Guillemette, Morgan & Catt [(1986) Proc. Natl. Acad. Sci. 83, 9323-9327].

Characterization of phosphoinositide-specific phospholipase C from human platelets

Phosphoinositide-specific phospholipase C (PI-PLC) from human platelet cytosol was purified 190-fold to a specific activity of 0.68 mumol of phosphatidylinositol (PI) cleaved/min per mg of protein. It hydrolyses PI and phosphatidylinositol 4,5-bisphosphate (PIP2), but not phosphatidylcholine, phosphatidylserine or phosphatidylethanolamine. The enzyme exhibits an acid pH optimum of 5.5 and has a molecular mass of 98 kDa as determined by Sephacryl S-200 gel filtration. It required millimolar concentrations of Ca2+ for PI hydrolysis, whereas micromolar concentrations are optimal for PIP2 hydrolysis. Mg2+ could substitute for Ca2+ when PIP2, but not PI, was used as the substrate. EDTA was more effective than EGTA in inhibiting the basal PI-PLC activity towards PIP2. Sodium deoxycholate strongly inhibits the purified PI-PLC activity with either PI or PIP2 as substrate. Ras proteins, either alone or in the form of liposomes, have no effect on PI-PLC activity.

Pathway for inositol 1,3,4-trisphosphate and 1,4-bisphosphate metabolism

We prepared [3H]inositol-,3-[32P]phosphate-and 4-[32P]phosphate-labeled inositol phosphate substrates to investigate the metabolism of inositol 1,3,4-trisphosphate and inositol 1,4-bisphosphate. In crude extracts of calf brain, inositol 1,3,4-trisphosphate is first converted to inositol 3,4-bisphosphate, then the inositol 3,4-bisphosphate intermediate is further converted to inositol 3-phosphate. Similarly, inositol 1,4-bisphosphate is converted to inositol 4-phosphate, and no inositol 1-phosphate is formed. We partially purified an enzyme that we tentatively name inositol polyphosphate 1-phosphatase. This cytosolic enzyme converts inositol 1,3,4-trisphosphate to inositol 3,4-bisphosphate and also converts inositol 1,4-bisphosphate to inositol 4-phosphate. The enzyme does not utilize inositol 1,3,4,5-tetrakisphosphate, inositol 1,4,5-trisphosphate, or inositol 1-phosphate as substrates. Thus we propose a new scheme for inositol phosphate metabolism. According to this pathway inositol 1,4,5-trisphosphate and inositol 1,4-bisphosphate are degraded to inositol 4-phosphate. Inositol 1-phosphate, which is the major inositol monophosphate formed in stimulated brain, is derived either from phospholipase C cleavage of phosphatidylinositol or from the degradation of inositol cyclic phosphates.

Inositol 1,2-cyclic 4,5-trisphosphate is not a product of muscarinic receptor-stimulated phosphatidylinositol 4,5-bisphosphate hydrolysis in rat parotid glands

We have employed a neutral-pH extraction technique to look for inositol 1,2-cyclic phosphate derivatives in [3H]inositol-labelled parotid gland slices stimulated with carbachol. The incubations were terminated by adding cold chloroform/methanol (1:2, v/v), the samples were dried under vacuum and inositol phosphates were extracted from the dried residues by phenol/chloroform/water partitioning. Water-soluble inositol metabolites were separated by h.p.l.c. at pH 3.7. 32P-labelled inositol phosphate standards (inositol 1-phosphate, inositol 1,2-cyclic phosphate, inositol 1,4,5-trisphosphate and inositol 1,2-cyclic 4,5-trisphosphate) were quantitively recovered through both extraction and chromatography steps. Treatment of inositol cyclic phosphate standards with 5% (w/v) HClO4 for 10 min prior to chromatography resulted in formation of the expected non-cyclic compounds. [3H]Inositol 1-phosphate and [3H]inositol 1,4,5-trisphosphate were both present in parotid gland slices and both increased during stimulation with 1 mM-carbachol. There was no evidence for significant quantities of [3H]inositol 1,2-cyclic phosphate or [3H]inositol 1,2-cyclic 4,5-trisphosphate in control or carbachol-stimulated glands. Parotid gland homogenates rapidly converted inositol 1,4,5-trisphosphate to inositol bisphosphate and inositol tetrakisphosphate, but metabolism of the inositol cyclic trisphosphate was much slower. The results suggest that inositol 1,4,5-trisphosphate, but not inositol 1,2-cyclic 4,5-trisphosphate, is the water-soluble product of muscarinic receptor-stimulated phospholipase C in rat parotid glands.

Synthesis of inositol 1,2-(cyclic)-4,5-trisphosphate

We have developed a method for synthesis of inositol 1,2-(cyclic)-4,5-trisphosphate from inositol 1,4,5-trisphosphate using a water-soluble carbodiimide. We obtained 1-1.5 mumol of the inositol cyclic trisphosphate starting with 5 mumol of inositol 1,4,5-trisphosphate. The cyclized product was isolated by HPLC on Partisil SAX. The identity of the cyclic product was verified by its hydrolysis to inositol 1,4,5-trisphosphate in acid and by its conversion to 1,2-(cyclic)-4-bisphosphate by a specific 5-phosphomonoesterase from platelets. We also identified the product by 31P NMR spectroscopy, which showed a peak at 17.2 ppm, characteristic of a five-membered cyclic phosphodiester ring, and peaks at 4.1 ppm and 0.8 ppm, indicative of phosphomonoesters. This relatively simple method for producing inositol 1,2-(cyclic)-4,5-trisphosphate will facilitate studies of the physiology of this compound in signal transduction.

Beyond receptors: multiple second-messenger systems in brain

Second-messenger systems play a major role in mediating neurotransmitter actions. In recent years our understanding of the organization and function of two prominent second-messenger systems has progressed rapidly--the adenylate cyclase and phosphoinositide systems. Guanosine triphosphate-binding proteins, which are especially abundant in brain, couple transmitter receptors to the key second-messenger generating enzymes in both of these systems. Whereas activation of adenylate cyclase produces a single intracellular messenger, cyclic AMP, stimulation of the phosphoinositide system generates at least two, inositol trisphosphate and diacylglycerol. Inositol trisphosphate mobilizes calcium from intracellular stores, and diacylglycerol, like cyclic adenosine monophosphate, activates a phosphorylating enzyme, protein kinase C. These second-messenger systems are particularly enriched in the brain where they modulate many aspects of synaptic transmission.

Evidence that inositol 1-phosphate in brain of lithium-treated rats results mainly from phosphatidylinositol metabolism

In cerebral cortex of rats treated with increasing doses of LiCl, the relative concentrations of Ins(1)P, Ins(4)P and Ins(5)P (when InsP is a myo-inositol phosphate) are approx. 10:1:0.2 at all doses. In rats treated with LiCl followed by increasing doses of pilocarpine a similar relationship occurs. myo-Inositol-1-phosphatase (InsP1ase) from bovine brain hydrolyses Ins(1)P, Ins(4)P and Ins(5)P at comparable rates, and these substrates have similar Km values. The hydrolysis of Ins(4)P is inhibited by Li+ to a greater degree than is hydrolysis of Ins(1)P and Ins(5)P. D-Ins(1,4,5)P3 and D-Ins(1,4)P2 are neither substrates nor inhibitors of InsP1ase. A dialysed high-speed supernatant of rat brain showed a greater rate of hydrolysis of Ins(1)P than of D-Ins(1,4)P2 and a lower sensitivity of the bisphosphate hydrolysis to LiCl, as compared with the monophosphate. That enzyme preparation produced Ins(4)P at a greater rate than Ins(1)P when D-Ins(1,4)P2 was the substrate. The amount of D-Ins(3)P [i.e. L-Ins(1)P, possibly from D-Ins(1,3,4)P3] is only 11% of that of D-Ins(1)P on stimulation with pilocarpine in the presence of Li+. DL-Ins(1,4)P2 was hydrolysed by InsP1ase to the extent of about 50%; both Ins(4)P and Ins(1)P are products, the former being produced more rapidly than the latter; apparently L-Ins(1,4)P2 is a substrate for InsP1ase. Li+, but not Ins(2)P, inhibited the hydrolysis of L-Ins(1,4)P2. The following were neither substrates nor inhibitors of InsP1ase; Ins(1,6)P2, Ins(1,2)P2, Ins(1,2,5,6)P4, Ins(1,2,4,5,6)P5, Ins(1,3,4,5,6)P5 and phytic acid. myo-Inositol 1,2-cyclic phosphate was neither substrate nor inhibitor of InsP1ase. We conclude that the 10-fold greater tissue contents of Ins(1)P relative to Ins(4)P in both stimulated and non-stimulated rat brain in vivo are the consequence of a much larger amount of PtdIns metabolism than polyphosphoinositide metabolism under these conditions.